2022年6月JSSC期刊：低损异质集成与W波段雷达应用

JSSC

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"JSSC 2022.06" 是一份关于电子和集成电路技术的学术期刊，包含了多个研究论文，涵盖了微波、射频、光学同步、振荡器、数字功率放大器、无线传输、相控阵天线以及高动态范围图像传感器等领域的最新研究成果。在这些论文中，第一篇是关于“低损耗异质集成在W波段高输出功率雷达应用”的研究，作者为X. Yang等人。他们探讨了如何通过异质集成技术来实现低损耗并提高W波段雷达系统的输出功率，这对于远程探测和目标识别具有重要意义。第二篇论文“CMOS中的光同步相控阵”由M. Gal-Katziri等人撰写，介绍了在互补金属氧化物半导体（CMOS）工艺中实现光同步相控阵的新方法，这可能提升无线通信系统中信号的同步性和精度。第三篇是关于“偶谐类-E CMOS振荡器”的工作，由M. Barzgari等人完成，他们设计了一种新型的CMOS振荡器，能够在保持低功耗的同时提高频率稳定性和谐波性能。第四篇论文是“15位四象限数字功率放大器”，由Y. Li等人提出，该放大器利用变压器基础的复域效率增强技术，旨在提升无线通信设备的功率效率和信号质量。第五篇是“220-GHz能量高效的高数据速率无线ASK发射阵列”，由B. Hadidian等人研发，他们的工作聚焦于实现高速无线通信，如64QAM操作，同时保持低能耗。第六篇论文展示了“八元素136-147GHz晶圆级相控阵发射机”，由S. Li等人设计，该发射机具有32dBm的峰值EIRP和超过16Gbps的数据传输能力，适用于毫米波通信系统。最后一篇是“A High Dynamic Range 128×120 3-D Stacked CMOS SPAD Image Sensor SoC for Fluorescence Microendoscopy”，由A. T. Erdogan等人撰写的关于高动态范围三维堆叠CMOS单光子雪崩二极管（SPAD）图像传感器系统级芯片，用于荧光内窥镜应用，提升了医学成像的细节和灵敏度。这些研究展示了当前集成电路领域在射频、微波、光学、功率放大和成像技术等方面的前沿进展，对于推动相关技术的发展和应用具有重要价值。

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1574 IEEE JOURNAL OF SOLID-STAT E CIRCUITS, VOL. 57, NO. 6, JUNE 2022

Fig. 30. (a) Image of range detection experiment using the FMCW radar.

(b) Corresponding range measurement results.

time is directly proportional to the distance. Range detection

is determined by analyzing the IF signal in the frequency

domain, which is proportional to the range. Detection range

theoretically depends on transmission power and noise ﬁgure.

The target resolution is determined by the sweep bandwidth.

A ranging detection experiment using the FMCW radar is

conducted, as shown in Fig. 30(a). Fig. 30(b) shows the range

measurement results. An radar cross-section (RCS) 400 m

corner reﬂector (CR) is placed on a tree and shows a high

peak at 60.7 m; the SNR is 25 dB. By contrast, a nearby

tree at 68 m has a lower peak, which indicates that the trees

have low reﬂections. In addition, two metal poles are 5 m,

an electrical bicycle is 12.5 m, and the Shanghai Jiao Tong

University (SJTU) logo is approximately 28.9 m. Evidently,

multiple peaks are noted at 28.9 m, ther eby indicating that

the logo has multiple reﬂections. The implication is that the

FMCW radar is able to detect long-distance targets because

of the 12 dB loss every double distance in the air.

Two 1 m

CRs with a 6 cm edge length are used to measure

the range resolution [Fig. 31(a)]. The CRs are placed at 4.5

and 4.65 m in front of the radar sensor. The measured range

Fig. 31. (a) Image of range resolution measurement. (b) Corresponding

resolution measurement results.

resolution is 11.7 cm [Fig. 31(b)], which corresponds to the

6 d B width of the target peak and is worse than the theoretical

result of 7.5 cm. The reason is that the Han window function

in fast Fourier transform (FFT) contributes to this difference

with a factor of 1.58 [32].

IX. S

TATE-OF-THE-ART COMPARISON

Table IV lists the comparison of similarly developed FMCW

radar senso rs that have been reported in recent y ears. The

resolution of our radar sensor is 11.7 cm, which represents a

36% difference with the theoretical results. The work in [8]

has a bandwidth of 26 GHz, and the resolution is 11.4 cm

mainly because of the unmatched passive circuits of the sys-

tem. Furthermore, our research has the highest output power,

including transitions to the antenna and the lowest noise ﬁgure.

The reason is that heterogeneous integration introduces low

loss in interconnections that are highly compact.

The system DR of our radar sensor is 55 dB, as determined

by the measurement with a 15 m

RCS CR located 2 m

away from the radar. In addition, the radar sensor measures

60 mm × 40 mm × 8 mm and has a width of 78 g. Overall,

YANG et al.: LOW-LOSS HETEROGENEOUS INTEGRATIONS WITH HIGH OUTPUT POWER RADAR APPLICATIONS AT W -BAND 1575

TABLE IV

OMPARISON OF SIMILAR STATE-OF-THE-ART W -BAND FMCW RADARS

this radar sensor shows outstanding performance in terms of

transmission power, receiver noise ﬁgure, and miniaturization

relative to other modern state-of-the-art radar systems.

X. C

ONCLUSION

This study presents the design and integration of a 94 GHz

high-performance and FMCW radar sensor by using a

silicon-based MEMS photosensitive composite ﬁlm fabrica-

tion process to heterogeneously integrate an X-band CMOS-

based PLL chip, W -band SiGe-based transceiver MMIC, and

W-band GaN-based MMIC PA. The schematics of each part

of the 130 nm BiCMOS SiGe-based transceiver MMIC are

introduced, along with the LNA, PA, octupler, mixer, and

Lange coupler. High-frequency interconnects between chips

are investigated, and they demonstrate extremely low insertion

loss at the W-band. The key points are the chip embedding

and alignments as varieties of chips have different materials,

sizes, thicknesses, and pads.

A total of 22 dBm output power and 10.2 dB noise ﬁgure are

obtained using on-wafer measurement. Bonding–SIW–WG

transitions between the heterogeneously integrated front end

and the antenna are speciﬁcally designed and veriﬁed, thereby

adding a 2.3 dB insertion loss. This result indicates an output

power of 19.7 dBm at the transmitter WG WR-10-ﬂange.

Range detection is experimentally measured. The result indi-

cates that the radar sensor is capable of long-distance target

detection range and 55 dB DR at 2 m away from the radar with

a15m

RCS CR. The measured range resolution is 11.7 cm,

which can be reasonably compared with the theoretical result

(i.e., 7.5 cm) because of the limitation o f the Han window

function during the FFT process.

The radar sen sor has high tra nsmitted power and low

receiver noise ﬁgure with high integration and low weight and

can thus be potentially used for SAR imaging.

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Xiao Yang (Student Member, IEEE) received the

B.S. and M.S. degrees in electromagnetic ﬁeld and

microwave techniques from the Univ ersity of Elec-

tronic Science and Technology of China (UESTC),

Chengdu, China, in 2015 and 2018, respectively.

He is currently pursuing the Ph.D. degree in elec-

tronic science and technology with Shanghai Jiao

Tong University (SJTU), Shanghai, China.

His research interests include millimeter-wave

integrated circuit and passive components design for

3-D heterogeneous inte gration applications.

Yin-Shan Huang (Graduate Student Member,

IEEE) received the B.S. degree in electronic sci-

ence and techniques from the University of Elec-

tronic Science and Technology of China (UESTC),

Chengdu, China, in 2019. He is currently pursuing

the Ph.D. degree in electronic science and technol-

ogy with Shanghai Jiao Tong University (SJTU),

Shanghai, China.

His current research interests include millimeter

wave phased array radar transceiver based on system

in packaging (SIP), 3-D RF front-end heterogeneous

integration and antenna in package design.

Liang Zhou (Senior Member, IEEE) received the

Ph.D. degree in electrical engineering from the Uni-

versity of York, York, U.K., in 2005.

At York he was working on ultralow phase noise

oscillators. From 2005 to 2006, he was a Senior

RF Engineer with Motorola INC, Shanghai, China,

where he in volved in power ampliﬁer design for

the next generation of base station transceivers.

From February 2017, he was a Research Fellow

with the Institute for Electronics Engineering (LTE),

Friedrich-Alexander-University Erlangen-Nurnberg,

Erlangen, Germany, granted by Alexander von Humboldt-Stiftung, Bonn,

Germany. He has been a Visiting Scholar with Massachusetts Institute of

Technology, Cambridge, MA, USA, since 2007. He is a Full Professor with

the Ke y Laboratory of Ministry of Education of Design and Electromag-

netic Compatibility of High-Speed Electronic Systems, Shanghai Jiao Tong

Uni versity (SJTU), Shanghai. His main research interests include system on

packaging (SOP) design and modeling, electromagnetic compatibility (EMC)

and high power microwave (HPM) protection of communication platforms,

and multiphysics and its applications.

Dr. Zhou was a recipient of the National Science and T echnology

Adva ncement Award of China in 2012, the International Union of Radio

Science (URSI) Young Scientist Award in 2014, the Best Paper Awards

of Cross Strait Quad-Regional Radio Wireless Conference (CSQRWC)

in 2014, the Alexander von Humboldt (AvH) Research Fellowship in 2016,

the APEMC Young Scientist Award in 2016, the Research Grant of the Okawa

Foundation (Japan) in 2016, and the National Science Fund for Excellent

Young Scholars in 2018. He was the IEEE EMC Distinguished Lecturer from

2019 to 2020 and is the IEEE EMC Shanghai Chapter Chair.

YANG et al.: LOW-LOSS HETEROGENEOUS INTEGRATIONS WITH HIGH OUTPUT POWER RADAR APPLICATIONS AT W -BAND 1577

Zhe Zhao received the B.S. degree in electronic

information engineering from Harbin Engineering

Uni versity (HEU), Harbin, China, in 2016, and

the M.S. degree in electrical engineering from The

Uni versity of Melbourne (UofMELB), Melbourne,

VIC, Australia, in 2019. He is currently pursuing the

Ph.D. degree in electronic science and technology

with Shanghai Jiao Tong Univ ersity (SJTU),

Shanghai, China.

His current research interests include millimeter-

wave and subterahertz ICs design for 3-D

system-on-package applications.

Dong-Xin Ni received the B.S. degree in elec-

tronic science and technology from the Southeast

Uni versity (SEU), Nanjing, China, in 2017. He is

currently pursuing the Ph.D. degree in electronic

science and technology with Shanghai Jiao Tong

Uni versity (SJTU), Shanghai, China.

From 2017 to 2020, he was a Student and a

RF Engineer with China Electronics Technology

Corporation (CETC), Ltd., Nanjing, where he was

involved with the design of RF front-end circuits.

His current research interests include millimeter-

wave and subterahertz integrated circuits design for 3-D system-on-package

applications.

Cheng-Rui Zhang (Member, IEEE) received the

B.S. degree in information science from the Univ er-

sity of Information Engineering, Zhengzhou, China,

in 1997, and the M.S. degree in electromagnetic

ﬁeld and microwav e techniques from the South-

west Electronics and Telecommunications Technol-

ogy Research Institute, Chengdu, China, in 2000.

From 2000, he was an Engineer with the South-

west Electronics and Telecommunications Technol-

ogy Research Institute at Shanghai Branch, Shang-

hai, China, where he became a Senior Engineer .

He is a Technician of the K ey Laboratory of Ministry of Education of

Design and Electromagnetic Compatibility of High-Speed Electronic Systems,

Shanghai Jiao Tong University (SJTU), Shanghai. His research interests

include microwave engineering and system-in-package.

Jun-Fa Mao (Fellow, IEEE) was born in 1965.

He received the B.S. degree in radiation physics

from the National Uni versity of Defense Technology ,

Changsha, China, in 1985, the M.S. degree in exper-

imental nuclear physics from Shanghai Institute of

Nuclear Research, Chinese Academy of Sciences,

Shanghai, China, in 1988, and the Ph.D. degree

in electronic engineering from Shanghai Jiao Tong

Uni versity (SJTU), Shanghai, in 1992.

He was a Visiting Scholar with The Chinese Uni-

versity of Hong Kong, Hong Kong, from 1994 to

1995, and a Post-Doctoral Researcher with the University of California at

Berkele y, Berkeley, CA, USA, from 1995 to 1996. Since 1992, he has been a

Faculty Member with SJTU, where he is currently the Chair Professor and the

Vice President. He is a Member of the Chinese Academy of Science, Beijing,

China. He has authored or coauthored more than 400 articles (including more

than 120 IEEE journal articles). His research interests include interconnect

and package problem of integrated circuits and systems, analysis and design

of microwave components and circuits.

Dr. Mao is a Fellow of China Institute of Electronics (CIE). He was

a member of the IEEE Microwave Theory and Techniques Society Fellow

Evaluation Committee from 2012 to 2014, a member of the IEEE Fellow

Committee Member 2015, the Founder and the Chair of the IEEE Shanghai

Section from 2007 to 2009. He was a recipient of the National Natural Science

Award of China in 2004, the National Technology Inv e ntion Award of China

in 2008, and the National Science and Technology Advancement Award of

China in 2012, earned six best paper awards of international conferences.

He also earned the two National Awards of Teaching in 2005 and 2018. He is

a Chief Scientist of the National Basic Research Program (973 Program)

of China, a Project Leader of the Natural Science Foundation of China

for Creative Research Groups, a Cheung Kong Scholar of the Ministry of

Education, China, the Director of the Microwave Society of CIE, and the

Chair of IEEE MTT-S Shanghai Chapter from 2009 to 2018.

Jiang-An Han was born in Guilin, China, in 1984.

He recei ved the B.Sc. and M.Sc. degrees from the

Uni versity of Electronic Science and Technology

of China, Chengdu, China, in 2008 and 2011,

respectively, and the Ph.D. degree from Nanyang

Technological University, Singapore, in 2016.

His research focuses on millimeter-wav e

(mm-W ave)/terahertz circuit and system design in

CMOS, and SiGe, GaAs, and GaN technologies.

Xu Cheng was born in 1987. He received the

B.E. degree in electromagnetics and wireless tech-

niques from the University of Electronic Science

and Technology of China, Chengdu, China, in 2009,

and the Ph.D. degree in microelectronics and solid-

state electronics from the Institute of Microelectron-

ics, Chinese Academy of Sciences, Beijing, China,

in 2014.

From 2014 to 2017, he was an Assistant Profes-

sor with the Microsystem and Terahertz Research

Center, China Academy of Engineering Physics,

Chengdu, where he has been an Associate Professor, since 2017. His current

research interests include microwa ve monolithic integrated circuits and analog

baseband circuit designs.

Xian-Jin Deng was born in Sichuan, China, in

June 11, 1973. He received the B.S. degree in elec-

tronic engineering from Xidian University, Xi’an,

China, in 1998, and the M.S. degree in electronic

science and techniques from the University of Elec-

tronic Science and Technology of China, Chengdu,

China, in 2006.

In 2003, he joined the Institute of Electronic

Engineering (IEE), China Academy of Engi-

neering Physics (CAEP), Mianyang, China. His

current research involves millimeter-wa ve (mm-

Wav e)/terahertz communication system, mm-Wave solid-state power combin-

ing, and micro wave active circuits.

1578 IEEE JOURNAL OF SOLID-STATE CIRCUITS, VOL. 57, NO. 6, JUNE 2022

Optically Synchronized Phased Arrays in CMOS

Matan Gal-Katziri , Member, IEEE, Craig Ives, Graduate Student Member, IEEE,

Armina Khakpour, Graduate Student Member, IEEE, and Ali Hajimiri

, Fellow, IEEE

Abstract—Optical synchronization of large-span arrays offers

signiﬁcant beneﬁts over electrical methods in terms of the

weight, cost, power dissipation, and complexity of the clock

distribution network. This work presents the analysis and design

of the ﬁrst phased array transmitter synchronized using a

fully monolithic CMOS optical receiver. We demonstrate a bulk

CMOS, 8-element, 28-GHz phased array building block with an

on-chip photodiode (PD) that receives and processes the optical

clock and uses an integrated PLL to generate eight independent

phase-programmable RF outputs. The system demonstrates beam

steering, data transmission, and remote synchronization of array

elements at 28 GHz with ﬁber lengths up to 25 m, in order

to show the scaling beneﬁts of our approach. The provision

of small footprint and cost-effective CMOS transceivers with

integrated optoelectronic receivers enables exciting opportunities

for low-cost and ultralight array systems.

Index Terms—CMOS, injection-locked oscillators (ILOs),

optoelectronics, phased arrays, photodiodes (PDs), silicon pho-

tonics.

I. INTRODUCTION

OW-COST, functionally complex silicon mm-wave and

RF integrated circuits (RFICs) [1]–[5] have signiﬁcantly

changed the nature and potential applications of phased arrays.

These RFICs enable very large span, low-cost, lightweight,

and ﬂexible phased arrays [6], which may be implemented in

a dense or sparse fashion [7], and used in a range of emerging

applications.

In a modern modular phased array, a common reference

signal is distributed to sub-modules, which are usually fully

functional phased arrays themselves. Each sub-module is gov-

erned by a single RFIC which drives several radiating elements

and performs local beamforming tasks that are essential for the

array’s functionality.

As array spans become large, electrically synchronizing

these submodules becomes more challenging. Methods for

Manuscript received April 28, 2021; revised August 27, 2021; accepted

December 8, 2021. Date of publication January 19, 2022; date of current

version May 26, 2022. This article was approved by Associate Editor

David Stoppa. This work was supported by the Caltech SSPP Program.

(Corresponding author: Matan Gal-Katziri.)

Matan Gal-Katziri was with the California Institute of Technology,

Pasadena, CA 91125 USA. He is now with the School of Electrical

Engineering, Ben-Gurion University, Be’er-Sheva 8443944, Israel (e-mail:

matangk@bgu.ac.il).

Craig Ives and Ali Hajimiri are with the California Institute of Technology,

Pasadena, CA 91125 USA.

Armina Khakpour was with the California Institute of Technology,

Pasadena, CA 91125 USA. She is now with Qualcomm Inc., San Diego,

CA 92121 USA.

Color versions of one or more ﬁgures in this article are available at

https://doi.org/10.1109/JSSC.2021.3136787.

Digital Object Identiﬁer 10.1109/JSSC.2021.3136787

reference distribution relying on local synthesis were intro-

duced [8]–[10], but are limited in performance. Clock distri-

bution at RF, on the other hand, may become prohibitively

expensive and power hungry. Neither of these options scales

well with the size, span, or operation frequency of the

array. Furthermore, as future arrays shift toward ﬂexible [6],

lightweight [5], and cost-effective [10] implementations, the

support infrastructure (Fig. 1) for reference, signal, and power

distribution becomes a dominant factor in the system’s cost,

power consumption, and mass.

Optical timing synchronization (OTS), where the timing

information is modulated onto an optical carrier and dis-

tributed over a long distance, can overcome some of the

challenges mentioned above in RF and digital systems. Optical

timing distribution has been envisioned in the past [11] and

has been realized in various applications today. Several radio

astronomy telescopes use or have used optical references to

synchronize remote antennas [12]–[15], and optical RF dis-

tribution plays a critical role in radio-over-ﬁber systems [16],

[17]. Some work has been done for optical distribution of

digital clocks using monolithic CMOS photodiodes (PDs) with

varying degrees of integration and success [18]–[20], while

other works implement data receiver building blocks using

monolithic CMOS PDs [21]–[23].

Considering the advantages of OTS and related prior work,

silicon RFICs using optical synchronization can beneﬁt a vari-

ety of applications. Indoors, applications that require multiple

modules distributed throughout a room can beneﬁt from OTS;

for example, mapping the interior of a house for robotic

navigation or creating 3-D models [Fig. 1(a)]. In order to

reach acceptable scanning resolutions of subcentimeter, these

systems have to either work in mm-wave frequency bands

or use interferometry. If mm-wave bands are used, obstacles

must be avoided to reduce losses, which requires multiple

antenna modules spread across the room, while interferometry

inherently requires multiple modules. Another example is

wireless power transfer, for which the avoidance of obstacles

may be desirable for efﬁciency and safety reasons, warranting

multiple modules as well. In all such cases, OTS provides a

low-cost and ﬂexible alternative to electrical wiring.

Outdoor terrestrial and space applications can also take

advantage of the physical ﬂexibility of OTS to enable large

arrays, possibly bendable and/or conformable, which may be

used in communications, radar, imaging, radio astronomy, and

so on. Moreover, constructing these systems out of a large

number of sub-modules enables economies of scale and design

ﬂexibility, such as hybrid solutions using OTS with local

electrical timing distribution, as illustrated in Fig. 1(b) and (c).

This work is licensed under a Creative Commons Attribution 4.0 License. For more information, see https://creativecommons.org/licenses/by/4.0/

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